Mechanistic View on the Order-Disorder Phase Transition in Amphidynamic Crystals

We combine temperature-dependent low-frequency Raman measurements and first-principles calculations to obtain a mechanistic understanding of the order-disorder phase transition of 2,7-di-tert-butylbenzo[b]benzo[4,5]thieno[2,3-d]thiophene (ditBu-BTBT) and crystals. We identify the lattice normal modes associated with the phase transition by following the position and width of the Raman peaks with temperature and identifying peaks that exhibit nonlinear dependence toward the phase transition temperature. Our findings are interpreted according to the hardcore mode model previously used to describe order-disorder phase transitions in inorganic and hybrid crystals with a Brownian sublattice. Within the framework of this model, ditBu-BTBT exhibits an ideal behavior where only one lattice mode is associated with the phase transition. TIPS-pentacene deviates strongly from the model due to strong interactions between lattice modes. We discuss the origin of the different behaviors and suggest side-chain engineering as a tool to control polymorphism in amphidynamic crystals.

Automated summary

We use temperature-dependent low-frequency Raman measurements and first-principles calculations to investigate the order-disorder phase transition of ditBu-BTBT crystals. By analyzing the Raman peaks and their dependence on temperature, we identify the lattice normal modes associated with the phase transition and propose a model to explain the observed behaviors. Our findings suggest that side-chain engineering can be used to control polymorphism in amphidynamic crystals by manipulating lattice interactions.